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Advanced Nuclear Magnetic Resonance

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the absorption of radiofrequencies (electromagnetic radiation) ... The best way to picture it is to imagine a spinning wooden top. under the action of gravity. ... – PowerPoint PPT presentation

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Title: Advanced Nuclear Magnetic Resonance


1
Advanced Nuclear Magnetic Resonance Spectroscopy
Guillermo Moyna - Spring 1999
Ala-Arg-Pro-Tyr-Asn-Phe-Cpa-Leu-NH2
Cpa
Ala
Pro
2
  • Why bother learning NMR?
  • Structural (chemical) elucidation
  • Natural product chemistry.
  • Synthetic organic chemistry. Analytical tool of
    choice of
  • synthetic chemists.
  • Study of dynamic processes
  • Reaction kinetics.
  • Study of equilibrium (chemical or structural).
  • Structural (three-dimensional) studies

3
  • The gory details
  • Absorption (or emission) spectroscopy, as IR or
    UV. Detects
  • the absorption of radiofrequencies
    (electromagnetic radiation)
  • by certain nuclei in a molecule.
  • Unfortunately, some quantum mechanics are needed
    to
  • understand it (a lot to really understand it).
  • Only nuclei with spin number (I) ? 0 can
    absorb/emit electro-
  • magnetic radiation.
  • Even atomic mass number ? I 0 (12C, 16O)
  • Even atomic mass odd number ? I whole
    integer
  • (14N, 2H, 10B)
  • Odd atomic mass ? I half integer (1H, 13C,
    15N, 31P)
  • The spin states of the nucleus (m) are
    quantified

4
  • Background (continued)
  • For 1H, 13C, 15N, 31P (biologically relevant
    nuclei) then
  • m 1/2, -1/2
  • This means that only two states (energy levels)
    can be
  • taken by these nuclei.
  • Another important parameter of each particular
    nuclei is
  • the magnetic moment (m), which can be expressed
    as
  • m g I h / 2p
  • It is a vector quantity that gives the direction
    and magnitude
  • (or strength) of the nuclear magnet

5
  • Effect of a magnetic field (for I 1/2)
  • In the ground state all nuclear spins are
    disordered, and there
  • is no energy difference between them. They are
    degenerate
  • Since they have a magnetic moment, when we apply
    a strong
  • external magnetic field (Bo), they orient
    either against or with it

g h / 4p
Bo
6
  • Energy and populations
  • Upon application of the external magnetic field
    we create an
  • energy difference between nuclei aligned and
    against Bo
  • Each level has a different population (N), and
    the difference
  • between the two is related to the energy
    difference by the
  • Boltzmman distribution

b
Bo gt 0
DE h n
a
Bo 0
7
  • Energy and sensitivity
  • The energy (for a single spin) is proportional
    to the magnetic
  • moment of the nuclei and the external magnetic
    field
  • E - m . Bo ? E(up) g h Bo / 4p ---
    E(down) - g h Bo / 4p
  • DE g h Bo / 2p
  • This has implications on the energy (i.e., the
    intensity of the
  • signal and sensitivity) that each nuclei can
    absorb
  • Bigger magnets (bigger Bo) make more sensitive
    NMR
  • instruments.
  • Nuclei with larger g absorb/emit more energy and
    are
  • therefore more sensitive. Sensitivity is
    proportional to

g13C 6,728 rad / G g1H 26,753 rad / G
1H is 64 times more sensitive than 13C just
because of the g
8
  • Energy and frequency
  • Since energy is related to frequency, we can do
    some
  • insightful math
  • DE h n
  • n g Bo / 2p
  • DE g h Bo / 2p
  • For 1H in normal magnets (2.35 - 18.6 T), this
    frequency is
  • in the 100-800 MHz range. For 13C, 1/4 of that

g-rays x-rays UV VIS IR m-wave
radio
10-10 10-8 10-6 10-4 10-2
100 102
wavelength (cm)
9
  • Precession and spinning tops
  • What precession is wo associated with? One thing
    that we
  • left out from the mix is the angular momentum,
    l, which
  • is associated with all nuclei
  • Crudely, we can think of the nuclei as being
    spinning around
  • its z axis. If we now consider those nuclei
    that have also a
  • non zero m, we have little spinning atomic
    magnets.
  • Now, if we bring about a big Bo, there will be
    an interaction
  • between m and Bo that generates a torque. No
    matter which
  • is the original direction of m, it will tend to
    align with Bo

l
Bo
Bo
m
or...
m
10
  • Precession (continued)
  • Now it starts getting exciting (?). Since the
    nuclei associated
  • with m is spinning due to l, there are two
    forces acting on it.
  • One that wants to bring it towards Bo, and one
    that wants to
  • keep it spinning. m ends up precessing around
    Bo
  • The best way to picture it is to imagine a
    spinning wooden top
  • under the action of gravity.

wo
m
Bo
11
  • Bulk magnetization
  • We see the effects on macroscopic magnetization,
    Mo, which
  • is directly proportional to the population
    difference (Na - Nb),
  • in which contributions from different ms have
    been averaged
  • We can decompose each little m in a z
    contribution and an
  • ltxygt plane contribution. The components in the
    ltxygt plane

z
z
Mo
x
x
y
y
Bo
Bo
12
  • Next class topics
  • Bulk magnetization and vector models.
  • Simple excitation of average magnetization.
  • Laboratory and rotating frames.
  • Chemical shift (d)
  • Spin-spin coupling (J). Energy diagrams for
    systems
  • of two coupled spins.
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